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Molecular Basis and Modification of a Neural Crest Deficit in a Down Syndrome Mouse ModelDeitz, Samantha L. 12 July 2013 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Down syndrome (DS) is the result of trisomy of human chromosome 21 (Hsa 21) and occurs in approximately 1/700 live births. Mouse models of DS have been crucial in understanding the gene-phenotype relationships that underlie many DS anomalies. The Ts65Dn mouse model, trisomic for half of the Hsa 21 orthologs replicates many DS phenotypes including craniofacial alterations such as a small, dysmorphic mandible, midface, and maxilla. Other mouse models, such as the Ts1Rhr which contains a triplication of 33 Hsa 21 orthologs, have been used to better understand the genes responsible for craniofacial alterations. Our laboratory has demonstrated that the postnatal mandibular phenotype found in Ts65Dn mice can be traced back to an original neural crest cell (NCc) deficit in the developing first pharyngeal arch (PA1) at embryonic day 9.5 (E9.5). Furthermore, evidence suggested that both a proliferation deficit in the PA1 and a migration deficit in the NCC from the neural tube (NT) could be the mechanism behind this deficit. However, the molecular mechanisms behind these deficits remain to be elucidated. Due to the involvement of the Hsa 21 genes DYRK1A and RCAN1 in regulation of signaling pathways including NFATc (NFAT2), a transcription factor known to influence cellular proliferation and, later, bone development, we hypothesized that dysregulation of these genes could underlie the cellular deficit in the PA1. Furthermore, we hypothesized that targeting Dyrk1a by decreasing activity or available protein could ameliorate the established deficits.
Through the use of RNA isolation techniques and cell culture systems of cell from the PA1 and NT of E9.5 Ts65Dn, Ts1Rhr, and control embryos, we established that trisomic genes Dyrk1a and Rcan1 ara dysregulated in both structures and that these two genes may interact. Furthermore, we established that a proliferation deficit in the Ts65Dn PA1 and a migration deficit in the Ts65Dn PA1 and NT exists at E9.5 and can be rescued to euploid levels in vitro with the addition of the Dyrk1a inhibitor, EGCG, a green tea polyphenol. We also confirmed that harmine, a more highly studied and specific Dyrk1a inhibitor, is capable of similar effects on proliferation of PA1 cell from E9.5 Ts65Dn embryos. Furthermore, when Ts65Dn pregnant mothers were treated with EGCG in vivo, the cellular deficit found in the developing E9.5 embryonic PA1 was rescued to near euploid volume and NCC number. Treatment with EGCG did not adversely impact litter size or embryonic development. Interestingly, euploid embryonic volume increased with EGCG treatment. Expression analysis of the E9.5 PA1 of EGCG treated Ts65Dn and control embryos revealed dysregulation of several genes involved in craniofacial and developmental pathways including Dyrk1a, Rcan1, Ets2 and members of the sonic hedgehog pathways. Our novel results provide a foundation for better understanding the molecular mechanisms of craniofacial development and may provide evidence-based therapeutic options to improve the quality of life for individuals with DS.
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Effect of Epigallocatechin-3-gallate on Skeletal and Cognitive Phenotypes in a Down Syndrome Mouse ModelAbeysekera, Irushi Shamalka January 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Down syndrome (DS), a genetic disorder that affects ~1 in 700 live births, is caused by trisomy of human chromosome 21 (Hsa21). Individuals with DS are affected by a wide spectrum of phenotypes which vary in severity and penetrance. However, cognitive and skeletal impairments can be commonly observed in all individuals with DS. To study these phenotypes, we utilized the Ts65Dn mouse model that carries three copies of approximately half the gene orthologs found on Hsa21 and exhibit similar phenotypes as observed in humans with DS. Individuals with DS and Ts65Dn mice have deficits in bone mineral density (BMD), bone architecture, bone strength, learning and memory. Over-expression of DYRK1A, a serine-threonine kinase encoded on Hsa21, has been linked to deficiencies in DS bone homeostasis and cognition. Epigallocatechin-3-gallate (EGCG), an aromatic polyphenol found in high concentrations in green tea, is a selective inhibitor of DYRK1A activity. Normalization of DYRK1A activity by EGCG therefore may have the potential to ameliorate skeletal and cognitive deficits. We hypothesized that supplements containing EGCG obtained from health food stores/ online vendors will not be as effective as EGCG from a chemical company in correcting bone deficits associated
with DS. Our results suggest that EGCG improves the bone mineral density of trisomic femurs significantly better than the supplements while the EGCgNOW supplement from NOW FOODS improves trabecular and cortical bone structure. The results from HPLC analysis of supplements showed the presence of other catechins in EGCgNOW and degradation analysis revealed the rapid degradation of supplements. Therefore we hypothesize that the presence of EGCG degradation products and other green tea catechins in supplements may play a role in the differential skeletal effects we observed. We further hypothesized that a three week treatment of adolescent mice with EGCG will lead to an improvement in the learning and memory deficits that are observed in trisomic animals in comparison to control mice. However, our results indicate that three weeks of low-dose EGCG treatment during adolescence is insufficient to improve hippocampal dependent learning and memory deficits of Ts65Dn mice. The possibility remains that a higher dose of EGCG that begins at three weeks but lasts throughout the behavioral test period may result in improvement in learning and memory deficit of Ts65Dn mice.
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